viable ednray129f mice feature human mandibulofacial dysostosis … · viable ednray129f mice...
TRANSCRIPT
Viable EdnraY129F mice feature human mandibulofacial dysostosiswith alopecia (MFDA) syndrome due to the homologue mutation
Sibylle Sabrautzki1,2 • Michael A. Sandholzer1,3 • Bettina Lorenz-Depiereux4 •
Robert Brommage1 • Gerhard Przemeck1,5 • Ingrid L. Vargas Panesso6,7 •
Alexandra Vernaleken6,7 • Lillian Garrett8 • Katharina Baron9 • Ali O. Yildirim3•
Jan Rozman1,5,10 • Birgit Rathkolb1,11 • Christine Gau1,5 • Wolfgang Hans1,5 •
Sabine M. Hoelter1,8 • Susan Marschall1 • Claudia Stoeger1 • Lore Becker1,5,6,7 •
Helmut Fuchs1,5 • Valerie Gailus-Durner1,5 • Martin Klingenspor10 •
Thomas Klopstock6,7,12 • Christoph Lengger1 • Leuchtenberger Stefanie1,5 •
Eckhard Wolf11 • Tim M. Strom4,15• Wolfgang Wurst8,12,13,14 • Martin Hrabe de Angelis1,5,16
Received: 27 June 2016 / Accepted: 21 August 2016 / Published online: 26 September 2016
� The Author(s) 2016. This article is published with open access at Springerlink.com
Abstract Animal models resembling human mutations are
valuable tools to research the features of complex human
craniofacial syndromes. This is the first report on a viable
dominant mouse model carrying a non-synonymous
sequence variation within the endothelin receptor type A
gene (Ednra c.386A[T, p.Tyr129Phe) derived by an ENU
mutagenesis program. The identical amino acid substitution
was reported recently as disease causing in three individuals
with the mandibulofacial dysostosis with alopecia (MFDA,
OMIM 616367) syndrome. We performed standardized
phenotyping of wild-type, heterozygous, and homozygous
EdnraY129F mice within the German Mouse Clinic. Mutant
mice mimic the craniofacial phenotypes of jaw dysplasia,
micrognathia, dysplastic temporomandibular joints, auricu-
lar dysmorphism, and missing of the squamosal zygomatic
process as described for MFDA-affected individuals. As
observed inMFDA-affected individuals, mutant EdnraY129F
mice exhibit hearing impairment in line with strong abnor-
malities of the ossicles and further, reduction of some lung
volumetric parameters. In general, heterozygous and
The authors wish it to be known that, in their opinion, the first three
authors should be regarded as joint first authors.
Electronic supplementary material The online version of thisarticle (doi:10.1007/s00335-016-9664-5) contains supplementarymaterial, which is available to authorized users.
& Martin Hrabe de Angelis
Sibylle Sabrautzki
Michael A. Sandholzer
Bettina Lorenz-Depiereux
Robert Brommage
Gerhard Przemeck
Ingrid L. Vargas Panesso
Alexandra Vernaleken
Lillian Garrett
Katharina Baron
Ali O. Yildirim
Jan Rozman
Birgit Rathkolb
Christine Gau
Wolfgang Hans
Sabine M. Hoelter
Susan Marschall
Claudia Stoeger
123
Mamm Genome (2016) 27:587–598
DOI 10.1007/s00335-016-9664-5
homozygousmice demonstrated inter-individual diversity of
expression of the craniofacial phenotypes as observed in
MFDApatients but without showing any cleft palates, eyelid
defects, or alopecia. Mutant EdnraY129F mice represent a
valuable viable model for complex human syndromes of the
first and second pharyngeal arches and for further studies and
analysis of impaired endothelin 1 (EDN1)–endothelin
receptor type A (EDNRA) signaling. Above all, EdnraY129F
mice model the recently published human MFDA syndrome
and may be helpful for further disease understanding and
development of therapeutic interventions.
Introduction
Studies in humans and in animal models have indicated an
essential role of the endothelin 1 (EDN1,2)–endothelin
receptor type A (EDNRA) signaling in normal craniofacial
development. Within the large family of syndromes of the
first and second pharyngeal arches, craniofacial deformities
in humans may occur as single characteristic without any
further organ anomalies, e.g., observed in auriculocondylar
syndrome (ACS, OMIM 602483, 614669, and 615706) due
to disruption of the EDNRA signaling pathway (Clouthier
et al. 2013; Gordon et al. 2013) or may occur with further
organ anomalies, e.g., observed in oculo-auriculo-vertebral
spectrum (OAVS, OMIM 164210). It was described for
mouse embryos and zebrafish larvae that Edn1 is required
for the formation of ventral arch cartilage and bones
(dentary, hyoid, thyroid, and tympanic ring bone), while
the formation of more proximal cartilage and bones such as
maxilla, palatine, and pterygoid is inhibited (Clouthier
et al. 2010). Thus, in ACS as a well-characterized rare
craniofacial disorder affecting early neural crest cell (NCC)
development within the first and second pharyngeal arches,
clinical characteristics manifest usually within structures
developed from differentiated NCCs like the bones of the
upper and lower jaw, the ossicles, the outer ear, and the
neck (Passos-Bueno et al. 2009; Ruest and Clouthier 2009).
In addition to several other genes, mutations of EDN1 were
reported to cause auriculocondylar syndrome 3 in patients
(ARCND3, OMIM 615706) (Gordon et al. 2013). In mouse
models, mutations of genes of the endothelin-1 pathway led
to craniofacial symptomatology, as mice harboring a tar-
geted mutation either in Edn1 (MGI:95283), Ednra
(MGI:105923), or the endothelin-converting enzyme-1
gene (Ece1; MGI:1101357) coding for an enzyme
responsible for the processing of inactive big-EDN1 to
active EDN1 were born with craniofacial and cardiovas-
cular malformations (Kurihara et al. 1994; Clouthier et al.
1998; Yanagisawa et al. 1998; Kitazawa et al. 2011).
Examining abnormalities associated with disruptions in
Lore Becker
Helmut Fuchs
Valerie Gailus-Durner
Martin Klingenspor
Thomas Klopstock
Christoph Lengger
Leuchtenberger Stefanie
Eckhard Wolf
Tim M. Strom
Wolfgang Wurst
1 Institute of Experimental Genetics and German Mouse
Clinic, Helmholtz Zentrum Munchen, German Research
Center for Environmental Health (GmbH), Ingolstadter
Landstr.1, 85764 Neuherberg, Germany
2 Research Unit Comparative Medicine, Helmholtz Zentrum
Munchen, German Research Center for Environmental
Health (GmbH), Ingolstadter Landstr.1, 85764 Neuherberg,
Germany
3 Comprehensive Pneumology Center, Institute of Lung
Biology and Disease, Helmholtz Zentrum Munchen,
Ingolstadter Landstr.1, 85764 Neuherberg, Germany
4 Institute of Human Genetics, Helmholtz Zentrum Munchen,
German Research Center for Environmental Health (GmbH),
Ingolstadter Landstr.1, 85764 Neuherberg, Germany
5 German Center for Diabetes Research (DZD), Neuherberg,
Germany
6 Department of Neurology, Friedrich-Baur-Institut, University
Hospital of LMU Munich, Ziemssenstr. 1, 80336 Munich,
Germany
7 German Center for Vertigo and Balance Disorders,
81377 Munich, Germany
8 Institute of Developmental Genetics, Helmholtz Zentrum
Munchen, German Research Center for Environmental
Health (GmbH), Ingolstadter Landstr.1, 85764 Neuherberg,
Germany
9 Ludwig-Boltzmann Gesellschaft GmbH, Ludwig-Boltzmann
Institut for Clinical-Forensic Imaging (LBI CFI),
BioTechMed Graz, Universitatsplatz 4/2, 8010 Graz, Austria
588 S. Sabrautzki et al.: EdnraY129F model for MFDA syndrome
123
these mouse genes was limited so far as knockouts
exhibited embryonic or neonatal lethality.
Recently, sequence analysis of one patient with severe
craniofacial abnormalities, alopecia, ear malformations,
and conductive hearing loss in line with developmental
delay, originally described for Johnson–McMillin syn-
drome (Cushman et al. 2005), revealed that these abnor-
malities were due to a de novo missense mutation within
the EDNRA gene as additionally isolated in two other
patients. Thus, a new syndrome was suggested as
mandibulofacial dysostosis with alopecia (MFDA, OMIM
616367) (Gordon et al. 2015).
Here, we describe a new viable EdnraY129FMhda mouse
model carrying the homologue point mutation of the three
patients reported with MFDA (Gordon et al. 2015). The
model was derived by the Munich N-ethyl-N-nitrosourea
(ENU) mutagenesis project used for more than a decade as
a forward genetic approach to generate mutant mouse
models for inherited human diseases (Hrabe de Angelis
et al. 2000; Sabrautzki et al. 2012). Using the standardized
phenotyping platform of the German Mouse Clinic (GMC)
(Gailus-Durner et al. 2009; Fuchs et al. 2012), we observed
a diversity of dysmorphological, otolaryngeal, and lung
phenotypes by comparison of adult heterozygous (Ed-
nraY129F/?) and homozygous (EdnraY129F/Y129F) mice with
their wild-type littermates (Ednra?/?). Our results may
contribute to reveal single-gene contribution in MFDA and
may be helpful to develop a treatment strategy for patients
(Gordon et al. 2015).
Materials and methods
ENU mutagenesis and mice
ENUmutagenesis was performed on the pure inbred C3HeB/
FeJ (C3H) mouse strain purchased originally from the Jack-
son Laboratory (Bar Harbour,Maine) as previously described
(Aigner et al. 2011; Sabrautzki et al. 2012). The mice were
housed and handled according to the federal animal welfare
guidelines and the responsible authority of Upper Bavaria
approved all animal studies (Reference Numbers 55.2-1-54-
2532-78-06 and 55.2-1-54-2532-144-10). The mouse line
was given the internal lab code AEA001 (abnormal ear #1)
according to the big bat-like ears. Heterozygous intercrosses
led to homozygous offspring in a Mendelian ratio that were
smaller than heterozygous littermates and showed bigger
ears. After the causative mutation was isolated, the mouse
line was given the official name EdnraY129FMhda.
Phenotyping in the GMC
Phenotyping was performed in the GMC according to the
standardized IMPReSS protocols (www.mousephenotype.
org). Depending on the individual screens, cohorts of 9–15
EdnraY129F/?, EdnraY129F/Y129F, and Ednra?/? mice per
gender were analyzed in the age of 9–16 weeks. Pheno-
typing was performed by a total of fourteen independent
screens (Fuchs et al. 2011). A summary of all phenotyping
protocols is provided in Table S1.
pQCT measurement
Femur midshafts and distal metaphyses of EdnraY129F/?
mice were scanned by pQCT (Norland Stratec XCT,
Stratec Medizintechnik GmbH, Pforzheim, Germany) at 3,
6, 9, and 12 months of age for the analyses of total bone
area, bone mineral content (BMC), and bone mineral
density (BMD) without distinguishing between cortical and
trabecular bone. Two pQCT scan slices were obtained at
each site, with voxel dimensions of 70 9 70 9 500 lmproviding data for 1 mm of bone length.
Micro-CT analysis and cephalometric measurement
Adult skulls (26- to 30-week-old mice) were imaged using
a SkyScan 1176 in vivo CT (Bruker micro-CT N.V.,
Kontich, Belgium) at 9 lm pixel resolution using 100 kV
voltage, 100 mA current, and a 0.5 mm aluminum filter.
The resulting slices were reconstructed with SkyScan’s
NSRECON package using uniform attenuation coefficient
data as previously described (Sabrautzki et al. 2013;
Sandholzer et al. 2014). In total, eight datasets were eval-
uated by two experienced osteologists using the distance
10 Molecular Nutritional Medicine, Else Kroner-Fresenius
Center and ZIEL Research Center for Nutrition and Food
Science, Technische Universitat Munchen, Gregor-Mendel-
Str. 2, 85350 Freising-Weihenstephan, Germany
11 Gene Center of the Ludwig-Maximilians-Universitat
Munchen, Chair for Molecular Animal Breeding and
Biotechnology, Ludwig-Maximilians-Universitat Munchen,
Feodor-Lynen-Str. 25, 81377 Munich, Germany
12 Munich Cluster for System Neurology (SyNergy), Adolf-
Butenandt-Institut, Ludwig-Maximilians-Universitat
Munchen, Schillerstr. 44, 80336 Munich, Germany
13 Chair of Developmental Genetics at Technische Universitat
Munchen-Weihenstephan, Helmholtz Zentrum Munchen,
Ingolstadter Landstr.1, 85764 Neuherberg, Germany
14 German Center for Neurodegenerative Diseases (DZNE) Site
Munich, Feodor-Lynen-Str. 17, 81377 Munich, Germany
15 Institut fur Humangenetik, Klinikum rechts der Isar der
Technischen Universitat Munchen, Trogerstr. 32,
81675 Munich, Germany
16 Lehrstuhl fur Experimentelle Genetik, Technische
Universitat Munchen, 85350 Freising-Weihenstephan,
Germany
S. Sabrautzki et al.: EdnraY129F model for MFDA syndrome 589
123
measurement tool of 3DSlicer 4.5 (available online: www.
slicer.org). Cranial and mandibular reference points on the
bone surface (Fig. 1) were selected based on previously
described landmarks (De Carlos et al. 2011). Soft-tissue
contrast enhancement was reached by staining with an
Iodine–Potassium Iodine solution for 2 weeks, with the
solution exchanged every 48 h.
Whole mount analysis of middle and inner ears
Samples were fixed in paraformaldehyde, dehydrated in
ethanol series, and made translucent using methyl-salicy-
late. Afterwards, the translucent inner ears were observed
and photographed using top and bottom illumination under
the microscope.
Lung analysis
For analysis of pulmonary function, five Ednra?/?, six Ed-
nraY129F/?, and sixEdnraY129F/Y129F femalemice were used.
The anesthetized mice were tracheotomized and ventilated
during the experiment. Briefly, a FinePointe RC system
(Buxco, Wilmington, USA) was used to measure dynamic
lung compliance (Cdyn) and resistance. Afterwards, the
mice were transferred to a Biosystem XA forced maneuvers
system (Buxco, Wilmington, USA) to measure forced
expiratory volume in 0.1 s (FEV0.1), forced vital capacity
(FVC), functional residual capacity (FRC), total lung
capacity (TLC), tidal volume (TV), inspiratory capacity
(IC), expiratory reserve volume (ERV), vital capacity (VC),
residual volume (RV), and static lung compliance (Cchord).
Statistical analyses
Statistical analyses were done using t test, Wilcoxon rank-
sum test, linear models, or ANOVAs, depending on the
assumed distribution of the parameter and the questions
addressed to the data. A P value\0.05 has been used as the
level of significance; a correction for multiple testing has
not been performed.
Genetic mapping
For genetic mapping, phenotypically heterozygous mice
were backcrossed with C57BL/6J (B6) mice, and DNA was
extracted from tail tips from 44 mutant and 37 wild-type
B6–C3H hybrid mice for linkage analysis as described
previously (Aigner et al. 2011). Genotyping was performed
by single-nucleotide polymorphism (SNP) analysis using
MassExtend (MALDI-TOF MS genotyping system) (Se-
quenom, San Diego, CA, USA) as previously described
(Sabrautzki et al. 2012).
Exome sequencing
DNA extraction from the spleens was performed using
ProteinaseK, RNaseA, CellLysis Solution, Protein Precip-
itation Solution, and DNA Hydration Solution from Qiagen
according to the manufacturer’s manual (Qiagen, Venlo,the
Netherlands). In-solution targeted enrichment of exonic
sequences from both the phenotypically mutant and the
control wild-type littermate mouse using the SureSelectXT
Mouse All Exon kit (Agilent, Santa Clara, CA, USA) was
Fig. 1 Landmarks of
cephalometric/mandibular
measurement
590 S. Sabrautzki et al.: EdnraY129F model for MFDA syndrome
123
performed. Libraries were sequenced as 100 bp paired-end
runs on a HiSeq 2000 system (Illumina, San Diego, CA,
USA). Read alignment to mouse genome assembly mm9
was done with Burrows-Wheeler Aligner (BWA, version
0.5.9), and a total of 10 and 9.2 Gb of mapped sequence
data corresponding to an average coverage of 1209
([95 % of the target being covered[209) and 1139 for
the mutant and control, respectively, were yielded. Single-
nucleotide variants (SNVs) and small insertions and dele-
tions (indels) were detected with SAMtools (v. 0.1.7).
Results
Genotypic identification of a new ENU-derived
mouse model
Using the sources of the large-scale genome-wide Munich
ENU mutagenesis project (MEP), a mouse line with cran-
iofacial and ear abnormalities was identified (AEA001,
abnormal ear #1), thereby showing an autosomal dominant
mode of inheritance. Linkage analysis gave a highest Chi
square for a region on chromosome eight between the
genomic markers rs13479782 and rs13479952 (NCBI137/
mm9_chr8:60,521,202-103,433,460, *43 Mb, UCSC).
Due to the high number of candidate genes within this large
region, we performed whole exome sequencing for mutation
detection. By comparing and filtering the sequencing data as
described previously (Sabrautzki et al. 2013; Diener et al.
2016), we obtained 11 candidate SNVs. Three candidate
SNVs were located within the candidate linkage interval on
mouse chromosome8.Although linkage datawere available,
we decided to analyze all 11 variants of interest within a
cohort of 10 wild-type and 16 mutant mice by capillary
sequencing. Only one SNV on mouse chromosome 8,
genomic position NCBI137/mm9_chr8:80,243,961, segre-
gated in all mutant mice analyzed with the phenotype. This
private SNVwas a heterozygous non-synonymous sequence
variation within the Ednra gene (NM_010332.2:c.386A[T,
NP_034462.1:p.Tyr129Phe). Thus, the AEA001 mouse line
was renamed as EdnraY129FMhda. Recently, in humans the
non-synonymous sequence variation within the EDNRA
gene at the corresponding position (NM_001957.3:c.
386A[T, NP_001948.1:p.Tyr129Phe) was published as
disease causing in three unrelated individuals with MFDA
(OMIM 616367) (Gordon et al. 2015).
Morphological changes in EdnraY129F mice
Mutant EdnraY129F mice showed craniofacial abnormali-
ties as short snout, round facial, and shortened head
appearance, further prominent cheeks, micrognathia, and
significantly malformed big bat-like ears (Fig. 2a, b, c).
The low-settled ears had a tapered helix, and the eyes of
some mice seemed to be enlarged. EdnraY129F/Y129F mice
were viable and fertile but displayed a visibly decreased
body size compared to Ednra?/? and EdnraY129F/? mice
with shortening and flattening of the skull in some but not
all EdnraY129F/Y129F mice. We observed a general inter-
individual variance in the severity of phenotype expression
among the mutant genotypes.
Fig. 2 Visible ear and eye abnormalities of EdnraY129F/? and
EdnraY129F/Y129F mice
S. Sabrautzki et al.: EdnraY129F model for MFDA syndrome 591
123
Micro-CT imaging of craniofacial phenotypes
Three-dimensional micro-CT analysis and measurements
revealed bones of the skull misshaped or underdeveloped
in EdnraY129F/? and EdnraY129F/Y129F mice (Fig. 3, Movies
M1–M3). The dorsal view depicted broadening of the
sagittal, coronal, and anterior lambdoid sutures of an Ed-
nraY129F/Y129F mouse (Fig. 3d) and broadened zygomatic
bones without any sutures in both EdnraY129F/Y129F mice
(Fig. 3d, e). In the lateral view, the absence of the zygo-
matic process of the squamosal bone was obvious in both
EdnraY129F/Y129F mice (Fig. 3i, j), as also seen in Ed-
nraY129F/? mouse #1 (Fig. 3g). In these three mice
(Fig. 3g, i, j), the zygomatic bone, connecting the malar
and squamosal zygomatic processes, appeared fused with-
out any suture (Movie M1). In addition, the shape of the
zygomatic bone was abnormal in these mice when com-
pared to the Ednra?/? mouse (Fig. 3f). In EdnraY129F/?
mouse #2 (Fig. 3h), the squamosal part of the zygomatic
process appeared to be present, as indicated by the exis-
tence of a suture but with a gap to the zygomatic bone.
Similar to the findings in MFDA patients, we observed
morphological changes of the orbit in mutant EdnraY129F
mice. The orbit appeared round and with thickened malar
zygomatic bone in EdnraY129F/Y129F mice, while in the
Ednra?/? mouse the orbit had an oval appearance. No
dental abnormalities or cleft palates were found in mutant
EdnraY129F mice. A malocclusion of molar teeth was
observed in EdnraY129F/Y129F mouse #2 (Fig. 3j) and a
minor malocclusion in EdnraY129F/? mouse #2 (Fig. 3h).
Altogether, the bone abnormalities of the skull in mutant
mice were highly similar to the changes found in clinical
CT scans of MFDA patients (Gordon et al. 2015).
Jaw dysplasia of the mandibular condyloid process was
visible in all mutant mice investigated (Fig. 3l, m, n, o;
Movie M2). In accordance with observations in MFDA
patients, EdnraY129F/? and EdnraY129F/Y129F mice showed
micrognathia by mandibular shortening of the diastema
(8.1 % in three EdnraY129F/? and 14.6 % in two Ed-
nraY129F/Y129F mice; Table 1). Furthermore, an abnormal-
ity of the temporomandibular joint in mutant mice was
evident (Movie M3).
Hearing impairment
In line with the conductive hearing loss of all MFDA
patients (Gordon et al. 2015), mild hearing impairment was
observed in EdnraY129F/? mice. An even stronger hearing
loss in EdnraY129F/Y129F mice was demonstrated by audi-
tory brainstem response ABR analysis with thresholds
increased by 25 and 50 dB, respectively, compared to the
thresholds obtained for Ednra?/? mice for both click
(Fig. 4a) and pure tone stimuli (Fig. 4b). Conductive
hearing impairment for mutant mice was further affirmed
by behavioral tests. Acoustic startle reactivity was signifi-
cantly decreased (P\ 0.001) in EdnraY129F/Y129F mice
compared to Ednra?/? and EdnraY129F/? mice (Fig. S1).
Moreover, there was decreased prepulse inhibition (PPI) in
mutant mice, with a significant reduction in EdnraY129F/
Y129F mice at all prepulse intensities (Fig. S2).
Malformations of the malleus and incus were found by
micro-dissections of the ossicles in adult mice. The malleal
bodies appeared slimmer with planar-shaped facets in
mutant mice, and stronger changes were seen in EdnraY129F/
Y129F mice. The short process of the incus was missing in
both mutant mice. Dissection of the petrosal bone revealed
Fig. 3 Micro-CT analysis of the dorsal (a–e), left lateral view (f–j) of the skull and lateral view of the mandible (k–o)
592 S. Sabrautzki et al.: EdnraY129F model for MFDA syndrome
123
abnormal closure of the ringbone and confirmed abnormally
shaped incudo-malleal joints in the mutant mice (Fig. 5).
Decreased lung volumetric parameters
Two of the MFDA patients showed upper airway
obstruction necessitating tracheostomy (Gordon et al.
2015). In the micro-CT datasets of contrast-enhanced soft
tissue of the upper airways, no clearly visible morpholog-
ical changes were observed (data not shown). The lung
function analysis showed that EdnraY129F/? and Ed-
nraY129F/Y129F mice concomitantly exhibited decreased
volumetric parameters in lung function analysis for IC, VC,
ERV, and TLC with genotype-related severity for some
parameters. In EdnraY129F/Y129F mice, further to volumetric
parameters FVC and forced expiratory volume (FEV 100)
as flow parameters were significantly decreased. Addi-
tionally, one mechanical parameter, the Cchord, was
decreased in EdnraY129F/Y129F mice (Table 2).
Additional minor findings
Besides the observed major craniofacial abnormalities, we
also found mild morphologic postcranial bone changes.
Femoral metaphyseal and diaphyseal bone area in mice,
BMC, and BMD measured at 3, 6, 9, and 12 months of age
were slightly reduced in EdnraY129F/? male and female
mice but these reductions did not consistently reach sta-
tistical significance. Averaging values for males and
females over all ages gave reductions of 6, 5, and 0 % for
Table 1 Craniometric and
mandibular measurements of
eight Ednra mice (Ednra?/?
n = 3, EdnraY129/? n = 3,
EdnraY129F/Y129F n = 2)
ID Genotype A [1–2] B [3–4] C [3–5] D [4–5] E [6–7] Ratio C/A
1 Ednra?/? 6.19 11.8 11.8 3.6 23.9 1.91
2 Ednra?/? 6.11 11.5 11.4 3.5 23.1 1.87
3 Ednra?/? 6.23 10.9 11.1 3.4 23.9 1.78
4 EdnraY129F/Y129F 6.61 11.3 11.1 3.2 22.1 1.68
5 EdnraY129F/? 6.25 11 10.7 3.1 22 1.71
6 EdnraY129F/? 6.35 11.1 10.9 3 22.4 1.72
7 EdnraY129F/Y129F 6.96 10.9 11.2 2.6 23.3 1.61
8 EdnraY129F/Y129F 6.82 10.3 10.6 2.5 22.6 1.55
Mean C/A ratio Ednra?/? 1.85 EdnraY129F/? 1.70 EdnraY129F/Y129F1.58
Measurement points: (1) palatinal intra-incisor-alveolar point, (2) palatinal-molar-alveolar point, (3) buccal
incisor-alveolar point, (4) most inferior point of the Processus condylaris, (5) most superior posterior point
of the Processus angularis, (6) most dorsal point of the Foramen magnum at the Os occipitale, and (7) most
caudal point of the Os nasale. Mean distance in mm
Fig. 4 ABR thresholds for click and tone-evoked potentials in Ednra+/+, EdnraY129F/+, and EdnraY129F/Y129F mice
S. Sabrautzki et al.: EdnraY129F model for MFDA syndrome 593
123
diaphyseal area, BMC, and BMD, respectively (Fig. S3).
Similarly, metaphyseal area, BMC, and BMD were
reduced 3, 5, and 1 %, respectively.
EdnraY129F/Y129F mice appeared with a visible reduced
body size, as observed in Endra-/- P0 mice (Clouthier
et al. 1998), and also significantly reduced body weight
(P\ 0.001). Mean body weight was 23.58 ± 2.35 g in
female and 28.31 ± 3.57 g in male EdnraY129F/Y129F mice
(female Ednra?/?: 28.65 ± 3.21 g; male Ednra?/?:
33.33 ± 3.41 g) in twelve-week-old mice. At the same
age, in EdnraY129F/Y129F but not in EdnraY129F/? mice
(n = 15 for all groups), body mass was significantly
reduced in NMR measurement (P\ 0.001).
We did not observe alterations in analyses of the allergy,
eye, clinical–chemical, cardiovascular, immunology, neurol-
ogy, nociception, pathology, and steroid metabolism screen.
Parameters showing only mild tendencies to alterations were
not considered. All phenotypic data are shown on the GMC
webpage (www.mouseclinic.de) under the line codeAEA001.
Discussion
EDNRA has been shown to play a key role in craniofacial
development (Clouthier et al. 2010; Twigg and Wilkie
2015). Detailed studies on the molecular regulation of
Fig. 5 Middle and inner ears of
Ednra+/+ (left), EdnraY129F/+
(middle), and EdnraY129F/Y129F
(right) mice
594 S. Sabrautzki et al.: EdnraY129F model for MFDA syndrome
123
craniofacial patterning were already performed using zeb-
rafish, chick, and mouse embryos as targeted gene models
(Miller et al. 2000; Ruest and Clouthier 2009; Zuniga et al.
2010). Here, we describe a new ENU mutagenesis-derived
mouse model carrying a non-synonymous sequence varia-
tion within the Ednra gene leading to a replacement of the
functionally important Tyr-129 residue within the trans-
membrane domain 2 of the receptor. In humans, the iden-
tical substitution is associated with the clinical spectrum of
MFDA (Gordon et al. 2015), whereby alopecia is distin-
guishing this syndrome from other mandibulofacial
dysostoses (MFD) (Wieczorek 2013). In EdnraY129F
mutant mice, numerous corresponding craniofacial char-
acteristics such as dysplastic zygomatic arch with missing
of the zygomatic process, micrognathia, dysplastic tem-
poromandibular joints, typical changes of the orbital mor-
phology, auricular dysmorphism, and conductive hearing
loss were observed.
In addition to the abnormalities observed in patients
with MFDA, we found volumetric airflow impairment in
our mouse model. Breathing impairment in patients with
MFDA was described due to upper airway obstruction
without any closer specification (Gordon et al. 2015). We
could not clearly detect any morphologic upper airway
obstructions in our mouse model by soft-tissue contrast-
enhanced micro-CT analysis so far. Nonetheless, female
EdnraY129F/? and EdnraY129F/Y129F mice showed decreased
volumetric parameters in lung function analysis. EDNRA
caused human cellular airway smooth muscle proliferation
when ligated to endothelin (Panettieri et al. 1996, 2008). In
tracheostomized E18.5 Ednra-null pups, no changes of
respiratory minute volume were observed but decreased
ventilatory responses following breathing of hypoxic gas,
suggesting that this observation was due to impaired early
central respiratory control (Clouthier et al. 1998). Whether
breathing impairment observed in MFDA-affected patients
and in our mouse model may derive from upper or lower
airway defects or both or are due to central defects is still
unclear.
MFDA-affected individuals presented severe outer
craniofacial malformations such as dysplastic zygomatic
arch and mandible and jaw deformity confirmed by clinical
CT scans of the skull. Broadening of the zygomatic bone
together with missing of the squamosal zygomatic process
was visible in some of the EdnraY129F/? and EdnraY129F/
Y129F mice, in line with deformities of the temporo-
mandibular joint. Three of the reported MFDA patients
with heterozygous de novo mutations within the EDNRA
gene were reported for conductive, but not specified,
hearing loss (Gordon et al. 2015). For hearing impairment
and cephalometric measurements in our mouse line, we
found significant differences between Ednra?/?, Ed-
nraY129F/?, and EdnraY129F/Y129F mice with a gene-dosage
effect in mutant mice. More strikingly and in contrast to
E18.5 Ednra-null embryos or newborn Ece-1-/- mice, in
which the malleus and incus as well as the tympanic ring
were completely missing (Clouthier et al. 1998; Yanagi-
sawa et al. 1998), we found malleus and incus malformed,
but almost normal stapes in EdnraY129F/? and EdnraY129F/
Y129F mice. The endothelin signaling plays an important
role in the development of skeletal elements that form the
middle ear, involving the tympanic ring and the auditory
ossicles (Ruest and Clouthier 2009). Malleus, incus, and
tympanic ring are endochondral bones that derive from the
first pharyngeal arch, while the stapes derive from the
second pharyngeal arch (Mallo and Gridley 1996). Chan-
ges in the morphology and organization of the ossicles may
impair the transmission of sound from the tympanic
membrane to the cochlear oval window. We propose that
the abnormal development of the tympanic ring affected
Table 2 Significant volumetric
parameter alterations following
lung function analysis of female
EdnraY129F/?, EdnraY129F/Y129F,
and Ednra?/? mice (mean
ml ± SD)
EdnraY129F/? EdnraY129F/Y129F Ednra?/?
Volumetric parameters
IC 0.967 ± 0.12 (P\ 0.05) 0.775 ± 0.097 (P\ 0.01) 1.138 ± 0.127
VC 1.32 ± 0.17 (P\ 0.05) 1.08 ± 0.12 (P\ 0.01) 1.56 ± 0.17
ERV 0.36 ± 0.06 (ns) 0.31 ± 0.04 (P\ 0.01) 0.42 ± 0.05
TLC 1.295 ± 0.161 (ns) 1.112 ± 0.07 (P\ 0.01) 1.496 ± 0.156
Flow parameters
FVC 1.082 ± 0.141 (P\ 0.05) 0.915 ± 0.109 (P\ 0.01) 1.348 ± 0.149
FEV100 0.923 ± 0.122 (ns) 0.835 ± 0.086 (P\ 0.01) 1.07 ± 0.097
Mechanical parameters
Cchorda 0.085 ± 0.0105 (ns) 0.0683 ± 0.01 (P\ 0.0098) 0.096 ± 0.012
Cchord static lung compliance, ERV expiratory reserve volume, FEV100 forced expiratory volume, FVC
forced vital capacity, IC inspiratory capacity, TLC total lung capacity, VC vital capacity, ns not significanta (ml/cm H2O)
S. Sabrautzki et al.: EdnraY129F model for MFDA syndrome 595
123
the normal development of the middle ear cavity and
tympanic membrane, thus causing aberrant three-dimen-
sional positioning of the ossicles in the auditory bulla of
our mice. We also hypothesize that the decreased acoustic
startle reaction and PPI inhibition were secondary effects
due to the hearing disability.
Ednra expression was shown for the first time in hair
and vibrissal follicles of E15.5 Ednralacz/? mouse embryos
(Gordon et al. 2015). So far, no viable mouse model was
available to study the impact of systemic impaired Ednra
function on hair development in adult mice. Yet, we did not
observe any alopecia in EdnraY129F/? or EdnraY129F/Y129F
mice as reported for MFDA-affected patients. Inherited
alopecia is correlated with a number of abnormalities
including hormonal factors, alterations of gene transcrip-
tion factors, impaired morphogenesis of hair follicles, and
other cell signaling pathways (Tomann et al. 2016).
However, how these and other underlying factors are ex-
actly linked to healthy or aberrant morphology, hair follicle
cycling, and subsequently hair loss is still unclear.
We further did not find any cleft palates in the analyzed
mice of our cohort so far, as we could not observe any cleft
palates in any of all our ENU mutagenesis-derived mouse
models (930 mouse lines, unpublished data). Although cleft
palates could be induced by triamcinolone in murine C3H
strains when administered at E11.5 (Andrew et al. 1973),
the C3H background probably is not sufficiently modeling
human cleft palates (Juriloff and Harris 2008).
Edn-1 as a ligand of Ednra seems to be a key player for
osteoblast differentiation by activating osteoblast signaling
pathways, e.g., by activating Wnt signaling in bone (Clines
et al. 2007), which additionally was shown by deletion of
the Edn-1 receptor (Ednra) in osteoblasts leading to
reduced bone mass (Clines et al. 2011). We observed only
minor reductions in bone mass in male and female Ed-
nraY129F/? mice examined between 3 and 12 months of
age. However, reductions in bone area and BMC were
consistent with reduced body size and normal BMD indi-
cating appropriately bone mass for slightly smaller bones,
thus suggesting that the postcranial skeleton was not
affected by the mutation.
However, we did not find any cleft palates, hypoplastic
eyelids, alopecia, or dental abnormalities. As observed in
MFDA-affected individuals, phenotypic outcome in our
mouse model resulted in high individual variability of the
phenotype. For some observations, a gene-dosage effect
could be demonstrated by comparing EdnraY129F/? with
EdnraY129F/Y129F mice.
So far, all available mouse models with a disruption of
the Ednra gene were embryonically or perinatally lethal
(Kurihara et al. 1994). In addition, no loss-of-function
(LoF) mutation within the EDNRA gene was observed
within the dataset of the human Exome Aggregation
Consortium (ExAC Browser, www.exac.broadinstitut.org)
providing exome sequencing data of 60,706 unrelated
individuals of various disease-specific and population
genetic studies. Instead of a complete loss of EDNRA such
as in Ednra-null mice, an impaired Ednra function due to a
change in ligand binding affinity caused by the Tyr-129
substitution (Krystek et al. 1994; Lee et al. 1994) leads to
the phenotype in EdnraY129F/? and EdnraY129F/Y129F mice
and patients with MFDA. Under physiological conditions,
the two different ligands Edn1 and Edn2 bind to the
G-protein-coupled Ednra, while all three ligands (Edn1–3)
are binding to the endothelin B receptor (Ednrb) with
specific affinities (Yanagisawa et al. 1998; Clouthier et al.
2010). We speculate that the substitution of Tyr-129 to Phe
within the binding side of the ligand in EDNRA could have
more than one effect, due to a reduction of Edn1/Edn2
receptor activation on one side and due to the gain of a
physiological unknown activation of the receptor by Edn3
on the other side. The question of whether the Tyr129Phe
exchange leads to a gain- or LoF mutation could not
entirely be answered by the phenotypes observed in human
patients and by zebrafish experiments (Gordon et al. 2015).
Targeted inactivation of Edn1, Ednra, or Ece1 in mouse
embryos caused the transformation of lower jaw structures
into maxillary derivatives (Abe et al. 2007), and vice versa,
mice ectopically overexpressing Edn1 showed an inverse
transformation of the upper jaw into a mandible-like
structure (Sato et al. 2008). Since the mutant EDNRA
could rescue the phenotype in zebrafish lacking the
endogenous Ednra genes, and further due to the malar
abnormalities, possibly appearing as mandible-like struc-
tures, the non-synonymous sequence variation was sug-
gested to be a gain-of-function mutation. Interestingly, in
one of the EdnraY129F/? mice analyzed in detail the
structures of the zygomatic arch obviously still did exist.
Thus, we suggest that the findings of micrognathia, mor-
phologic changes of the ossicles, and gene-dosage-depen-
dant hearing loss contribute more likely to a LoF mutation
hypothesis. Nevertheless, the murine phenotype is, like the
human and zebrafish phenotype, dependent on the complex
context-dependent regulation of the EDNRA signaling via
its physiological ligand during early craniofacial develop-
ment. Inter-individual penetrance of the phenotype was
observed in MFDA-affected individuals like in EdnraY129F/
? and EdnraY129F/Y129F mice. Incomplete penetrance of the
phenotype in autosomal dominant diseases may depend on
genetic and environmental factors such as modifier genes,
DNA sequence polymorphisms in regulatory elements, and
random monoallelic expression of autosomal genes, where
genes can be stably expressed, from either of the parental
alleles (Cooper et al. 2013; Gendrel et al. 2016).
In conclusion, EdnraY129F mice may serve as a valuable
model to analyze endothelin signaling in syndromes
596 S. Sabrautzki et al.: EdnraY129F model for MFDA syndrome
123
resembling abnormalities of tissues derived from the first
and second pharyngeal arches. We isolated the first viable
mouse model for a systemic Ednra mutation and showed
several bone abnormalities as observed in MFDA-affected
individuals, but in more detail. Moreover, our mouse model
could contribute to solve the so far open question on the
functional nature of the mutation. Above all, our mouse
model might be valuable for further analysis of symptoms
observed in MFDA-affected individuals and for respective
therapeutic interventions.
Summary statement
ENU mutagenesis-derived EdnraY129F mice mimic cran-
iofacial phenotypes of jaw dysplasia, micrognathia, dys-
plastic temporomandibular joints, auricular dysmorphism,
and missing of the squamosal zygomatic process as
described for MFDA-affected individuals.
Acknowledgments We thank Anja Wohlbier, Soren Kundt, Lisa
Fees, and the team of technical assistants of the GMC for excellent
technical assistance. We thank Sandy Losecke and Susanne Diener
for contributing to genetic analysis of the mouse model. We espe-
cially thank Sandra Hoffmann and Andreas Mayer for breeding per-
formance of the mouse model, tissue sampling, and genotyping.
Finding This work was supported by the Bundesministerium fur
Bildung und Forschung OSTEOPATH [Grant Number 01EC1006B],
Nationales Genomforschungsnetz [Grant Number NGFN 01GR0430],
Bundesministerium fur Bildung und Forschung NGFNplus grants
[Grant Numbers 01GS0850, 01GS0851], Bundesministerium fur
Bildung und Forschung grant to the German Center for Vertigo and
Balance Disorders [grant number 01EO0901], EU ANABONOS
[Grant Number LSH-2002-2.1.4-3], and Bundesministerium fur Bil-
dung und Forschung TAL-Cut-Technology grant [Grant Number
03V0261]. This work was also supported by the Helmholtz Portfolio
Theme ‘‘Metabolic Dysfunction and Common Disease.’’
Authors’ contribution Performance of the study and participation in
its design and coordination: SS, MAS, BLD, and MHdA. Drafting of
the manuscript: SS, MAS, and BLD. Project leader of the Munich
ENU mutagenesis project, generation of the AEA001 mouse line,
coordination of breeding and sample distribution of the obtained ENU
mouse lines, and phenotyping of blood samples: SS. Micro-CT set-
tings, measurements, data analysis, and preparation of images, fig-
ures, and movies: MAS. Sample preparation including exome capture
for exome sequencing, PCR, capillary sequencing, and RT-PCR
validation: BLD. Analysis of pQCT data: RB. Skeletal preparations:
GP. Ossicle dissection and preparation: ILVP. ABR analysis: AV.
Auditory brain stem and PPI analysis in the GMC: LG. Analysis of
skeletal landmarks of the skull: KB. Lung volumetric measurements
in the GMC: AOY. Coordination of body composition analysis in the
GMC: JR. Coordination of clinical chemistry analysis in the GMC:
BR. Statistical analysis in the GMC: CG. Coordination of dysmor-
phological phenotyping in the GMC: HF and WH. Coordination of
behavioral analysis in the GMC: SMH. Coordination of in vitro fer-
tilization, embryo transfer, and sperm freezing for rederivations of the
mouse line: SM. Coordination of mouse cohort breeding in the GMC:
CS. Coordinator of the neurology screen in the GMC: LB. Scientific
and Technical Head GMC: HF. Scientific Administrative Head GMC:
VGD. Head of the neurology screen in the GMC: TK. Coordinator of
data administration: CL. Manuscript coordinator in the GMC: LS.
Head of the behavior screen in the GMC: WW. Participation in the
conception of the mouse exome sequence and bioinformatics analysis,
and the statistical evaluation: TMS. Heads and responsible coordi-
nators of the ENU mutagenesis project: EW and MHdA. Director of
the GMC: MHdA. All the authors read and approved the manuscript.
Compliance with ethical standards
Conflict of interest The authors declare that they have no conflicts of
interest.
Open Access This article is distributed under the terms of the
Creative Commons Attribution 4.0 International License (http://crea
tivecommons.org/licenses/by/4.0/), which permits unrestricted use,
distribution, and reproduction in any medium, provided you give
appropriate credit to the original author(s) and the source, provide a
link to the Creative Commons license, and indicate if changes were
made.
References
Abe M, Ruest LB, Clouthier DE (2007) Fate of cranial neural crest
cells during craniofacial development in endothelin-A receptor
defined mice. Int J Dev Biol 51:97–105
Aigner B, Rathkolb B, Klempt M, Wagner S, Michel D et al (2011)
Generation of N-ethyl-N-nitrosourea-induced mouse mutants
with deviations in hematological parameters. Mamm Genome
22:495–505
Andrew FD, Bowen D, Zimmermann EF (1973) Glucocorticoid
inhibition of RNA synthesis and the critical period for cleft
palate induction in inbred mice. Teratology 7:167–175
Clines GA, Mohammad KS, Bao Y, Stephens O, Suva LJ et al (2007)
Dickkopf homologue 1 mediates endothelin-1-stimulated new
bone formation. Mol Endocrinol 21:486–498
Clines GA, Mohammad KS, Grunda JM, Niewolna Clines KL,
Niewolna M et al (2011) Regulation of postnatal trabecular bone
formation by the osteoblast endothelin A receptor. J Bone Miner
Res 26:2523–2536
Clouthier DE, Hosoda K, Richardson JA, Williams SC, Yanagisawa
H et al (1998) Cranial and cardiac neural crest defects in
endothelin-A receptor-deficient mice. Development
125:813–824
Clouthier DE, Garcia E, Schilling TF (2010) Regulation of facial
morphogenesis by endothelin signaling: insight from mice and
fish. Am J Med Genet A 152A:2962–2973
Clouthier DE, Passos-Bueno MR, Tavares AL, Lyonnet S, Amiel J
et al (2013) Understanding the basis of auriculocondylar
syndrome: insight from human, mouse and zebrafish genetic
studies. Am J Med Genet C 163C:306–317
Cooper DN, Krawczak M, Polychronakos C, Tyler-Smith C, Kehrer-
Sawatzki H (2013) Where genotype is not predictive of
phenotype: towards an understanding of the molecular basis of
reduced penetrance in human inherited disease. Hum Genet
132:1077–1130
Cushman LJ, Torres-Martinez W, Weaver DD (2005) Johnson-
McMillin syndrome: report of a new case with novel features.
Birth Defects Res A 73:638–641
de Carlos F, Alvares-Suarez A, Costilla A, Noval I, Vega JA et al.
(2011) 3D-lCT cephalometric measurements in mice. In: Saba L
(ed) Computed tomography—special applications. Chapter 9.
10.5772/24234. Available from http://www.intechopen.com/
S. Sabrautzki et al.: EdnraY129F model for MFDA syndrome 597
123
books/computed-tomography-special-applications/3d-ct-cephalo
metric-measurements-in-mice
Diener S, Bayer S, Sabrautzki S, Wieland T, Mentrup B et al (2016)
Exome sequencing identifies a nonsense mutation in Fam46a
associated with bone abnormalities in a new mouse model for
skeletal dysplasia. Mamm Genome 27:111–121
Fuchs H, Gailus-Durner V, Adler T, Aguilar-Pimentel JA, Becker L
et al (2011) Mouse phenotyping. Methods 53:120–135
Fuchs H, Gailus-Durner V, Neschen S, Adler T, Caminha Afonso L
et al (2012) Innovations in phenotyping of mouse models in the
German Mouse Clinic. Mamm Genome 23:611–622
Gailus-Durner V, Fuchs H, Adler T, Aguilar-Pimentel JA, Becker L
et al (2009) Systemic first-line phenotyping. Methods Mol Biol
530:463–509
Gendrel AV, Marion-Poll L, Katoh K, Heard E (2016) Random
monoallelic expression of genes on autosomes: parallels with
X-chromosome inactivation. Semin Cell Dev Biol 56:100–110
Gordon CT, Petit F, Kroisel PM, Jakobsen L, Zechi-Ceide RM et al
(2013) Mutations in endothelin 1 cause recessive auriculocondy-
lar syndrome and dominant isolated question-mark ears. Am J
Hum Genet 93:1–8
Gordon CT, Weaver KN, Zecchi-Ceide RM, Madsen EC, Tavares
ALP et al (2015) Mutations in the endothelin receptor type A
cause mandibulofacial dysostosis with alopecia. Am J Hum
Genet 96:519–531
Hrabe de Angelis M, Flaswinkel H, Fuchs H, Rathkolb B, Soewarto D
et al (2000) Genome-wide, large-scale production of mutant
mice by ENU mutagenesis. Nat Genet 25:444–447
Juriloff DM, Harris MJ (2008) Mouse genetic models of cleft lip with
or without cleft palate. Birth Defects Res A 82:63–77
Kitazawa T, Sato T, Nishiyama K, Asai R, Arima Y et al (2011)
Identification and developmental analysis of endothelin receptor
type-A expression cells in the mouse kidney. Gene Expr Patterns
11:371–377
Krystek SR Jr, Patel PS, Rose PM, Fisher SM, Kienzle BK (1994)
Mutation of peptide binding site in transmembrane region of a G
protein-coupled receptor accounts for endothelin receptor sub-
type selectivity. J Biol Chem 269:12383–12386
Kurihara Y, Kurihara H, Suzuki H, Kodama T, Maemura K et al
(1994) Elevated blood pressure and craniofacial abnormalities in
mice deficient in endothelin-1. Nature 368:703–710
Lee JA, Elliott JD, Sutiphong JA, Friesen WJ, Ohlstein EH et al
(1994) Tyr-129 is important to the peptide ligand affinity and
selectivity of human endothelin type A receptor. Proc Natl Acad
Sci USA 91:7164–7168
Mallo M, Gridley T (1996) Development of the mammalian ear:
coordinate regulation of formation of the tympanic ring and the
external acoustic meatus. Development 122:173–179
Miller CT, Schilling TF, Lee KH, Parker J, Kimmel CB (2000)
Sucker encodes a zebrafish endothelin-1 required for ventral
pharyngeal arch development. Development 127:3815–3828
Panettieri RA Jr, Goldie RG, Rigby PJ, Eszterhas AJ, Hay DW (1996)
Endothelin-1-induced potentiation of human airway smooth
muscle proliferation: an ETA receptor-mediated phenomenon.
Br J Pharmacol 118:191–197
Panettieri RA Jr, Kotlikoff MI, Gerthoffer WT, Hershenson MB et al
(2008) Airway smooth muscle in bronchial tone, inflammation,
and remodeling: basic knowledge to clinical relevance. Am J
Respir Crit Care Med 177:248–252
Passos-Bueno MR, Ornelas CC, Fanganiello RD (2009) Syndromes of
the first and second pharyngeal arches: a review. Am J Med
Genet A 159A:1853–1859
Ruest LB, Clouthier DE (2009) Elucidating timing and function of
endothelin-A receptor signaling during craniofacial development
using neural crest cell-specific gene deletion and receptor
antagonism. Dev Biol 328:94–108
Sabrautzki S, Rubio-Aliaga I, Hans W, Fuchs H, Rathkolb B et al
(2012) New mouse models for metabolic bone diseases gener-
ated by genome-wide ENU mutagenesis. Mamm Genome
23:416–430
Sabrautzki S, Janas E, Lorenz-Depiereux B, Calzada-Wack J,
Aguilar-Pimentel JA et al (2013) An ENU mutagenesis-derived
mouse model with a dominant Jak1 mutation resembling
phenotypes of systemic autoimmune disease. Am J Pathol
183:352–368
Sandholzer MA, Baron K, Heimel P, Metscher BD (2014) Volume
analysis of heat-induced cracks in human molars: a preliminary
study. J Forensic Dent Sci 6:139–144
Sato T, Kawamura Y, Asai R, Amano T, Uchijima Y et al (2008)
Recombinase-mediated cassette exchange reveals the selective
use of Gq/G11-dependent and -independent endothelin1/endothe-
lin type A receptor signaling in pharyngeal arch development.
Development 135:755–765
Tomann P, Paus R, Miller SE, Scheidereit C, Schmidt-Ullrich R
(2016) LHX2 is a direct NF-jB target gene that promotes
primary hair follicle placode down-growth. Development
143:1512–1522
Twigg SRF and Wilkie AOM (2015) New insights into craniofacial
malformations. Hum Mol Genet 24:R50–R59
Wieczorek D (2013) Human facial dysostoses. Clin Genet
83:499–510
Yanagisawa H, Yanagisawa M, Kapur RP, Richardson JA, Williams
SC et al (1998) Dual genetic pathways of endothelin mediated
intercellular signaling revealed by targeted disruption of
endothelin converting enzyme-1 gene. Development
125:825–836
Zuniga E, Stellabotte F, Crump JG (2010) Jagged-Notch signaling
ensures dorsal skeletal identity in the vertebrate face. Develop-
ment 137:1843–1852
598 S. Sabrautzki et al.: EdnraY129F model for MFDA syndrome
123